DE10146883B4 - Mineral raw material for the production of dental plaster models with a fluorescent surface - Google Patents

Abstract

Mineral model material based on calcium sulfate hemihydrate for the production of dental and dental plaster models whose surface fluoresces in the spectral range from 360 to 420 nm, characterized in that it consists of:
70-99% hydraulically setting calcium sulfate hemihydrate
0-25% non-setting fillers, preferably calcium carbonate
0-5% leveling agent, from the group of retarders, accelerators, crystallizers, nucleating agents and consistency regulators.
0-5% organic or inorganic color pigments
0.01-10% organic and / or inorganic fluorescent substances whose light emission is predominantly between 360 and 420 nm.

Description

The The invention relates to a calcium sulfate hemihydrate product for the preparation dental plaster models, which should be especially suitable for use on them processed novel waxy and light-curing modeling materials and before the transfer in secondary Working steps dimensionally stabilized by partial polymerization can be. Furthermore plaster models of similar composition should also be processed of wax-free light-curing Dental plastics serve by shortening their polymerization time.

In all fields of dentistry, namely the dental preservation, the Oral surgery, orthodontics but above all the dental Prosthetics become important and fundamental steps by the dental technician done on models that are preferably made of plaster. Of the Dental technicians and possibly also the dentist provide these Plaster models of commercial powdery Calcium sulfate hemi-hydrate products by mixing with water. For certain work will be of these plaster models in turn Duplicate models of refractory Materials produced.

On These models of gypsum or fireproof material manufactures the Dental technician and possibly also the dentist first off Wax preforming the intended dental replacement pieces. The actual dentures is then made of metallic materials in the lost wax process cast.

Because of the low strength of the wax, this technique is great for large, e.g. a complete Kiefer comprehensive reconstructions very problematic. To deformation during Therefore, instead of on the Gypsum model (master model) on a model made of refractory material (Duplicate model) worked. The latter can then indeed in the Gußmuffel be introduced with velvet the resting wax part, then but after the casting process destroyed.

Around the additional Effort for to make the production of a Duplicate model obsolete, is now In dentistry, offered a composite material whose wax with a light-curing plastic component combined. But this is the dental plaster material properties demanded that the previously commercially available calcium sulfate hemihydrate products only insufficient Take into account.

Next the technique of producing metallic dental prostheses in the lost wax process, are also dentures and dental Aid made from plastics. Also in these cases will be traditionally made on plaster models first a wax model, which then serves to create a cavity in a gypsum-filled cuvette, in which then finally the plastic polymerizes. Again, efforts are made to simplify procedures, by looking at the plaster model instead of a wax construction as Intermediate directly with the plastic, e.g. Denture Resin is working. He must then be light-curing, which also demands properties corresponding to the plaster model.

The only conditional suitability of commercially available calcium sulfate hemihydrate products for the production of plaster models for the new processing techniques is explained by their previous standard composition. Calcium sulfate hemihydrate products for dental plasters have the following typical composition worldwide: Calcium sulfate hemihydrate (80-99)% Non-setting fillers (0-20)% actuating means (0-2)% color pigments (0-5)%

usual and most used filler is calcium carbonate. fillers take influence the strength and the mixing water need, because they are not at the Abbindereaktion involved.

With adjusting agents preferably the processing properties and only indirectly on the mixing water requirement, the strength properties are affected. At the same time, different types of setting agents influence the setting expan- sion of the gypsum. One differentiates between retarders, accelerators, crystallizers, nucleating agents and consistency regulators, wherein certain actuating agents exert several influences simultaneously. So it comes to the layperson often incomprehensible combination that, for example, a certain calcium sulfate hemihydrate simultaneously contains a typical retarder and a typical accelerator.

you uses retarder especially with very fine-grained Hemihydrate, to extend the processing time. Common are citric acid or their alkali salts or the alkali or ammonium salts of various phosphoric acids, but especially the tartaric acid or the potassium sodium tartrate. Retarders already act in concentrations below 0.1%. Except the aforementioned substance groups are known to act as well delaying all substances, the viscosity increase the mixing water, such as. the sodium carboxymethylcellulose. Such substances However, they act only at concentrations well above 0.1%.

accelerating on the gypsum crystallization of calcium sulfate hemihydrate acts in principle high fines content of hemihydrate. Missing this will be chemical Accelerator used. Generally recognized as an accelerator is potassium sulfate in concentrations below 1%.

The Crystallization of the gypsum, ie the calcium sulfate double hydrate from the calcium sulfate solution in the mixing water requires nucleation. This can also be by crystallization nuclei in hemihydrate product anticipated become. This is known to serve a Feinstkornanteil of calcium sulfate double hydrate in the starting material. Depending on the fineness you can here with mass shares of significantly less than Get 1%.

nucleation this kind works by the way like an accelerator addition The crystallization of gypsum out a calcium sulfate hemihydrate suspension is basically with a negative volume reaction ver connected, that is one Contraction. As soon as the stiffening mixture stops flowable though not yet complete is tied, one observes an expansion.

The remaining difference from contraction and expansion is called setting expansion designated. It comes about because gypsum forms acicular crystals, which perpendicular to the Hauptwachstumsrichtung creates cavities, in the from a corresponding stiffening only additional mixing water can flow. The participants in the process Calcium sulphates could these cavities just fill in, if the gypsum crystals would grow uniformly on all sides. Around to avoid a setting expansion that is not permitted in dentistry have to therefore crystallizers are used which are able to to hinder the main growth direction of the forming gypsum crystals.

For this are one Variety of complexing organic acids and their alkali metal salts suitable. This includes dicarboxylic acids or their salts but also citric and tartaric acid with their alkali metal salts, already as retarders are in use. For calcium sulfate hemihydrate, in the suspension process was generated, crystallizers are process-related in the starting material contain. All usually Crystallizers used already react in mass fractions 0.1%.

Consistency regulators are on the one hand methyl or ethylcelluloses. They increase the viscosity and act as a retarder at the same time. In calcium sulfate hemihydrate products for dentistry they are without meaning. Consistency regulators are preferably used in Form of liquefiers used to reduce the amount of mixing water and thus the gypsum strength to increase. Sulfonates, preferably melamine sulfonates, are used here and with mass contents of up to 1%.

Except the aforementioned fillers and adjusters contain calcium sulfate hemihydrate products for dental Application color pigments. Virtually everyone comes between white and black Colors of the visible spectrum for use. Outweigh the pigments water commercial inorganic pigments. Even white products often contain pigment additives, e.g. the usual in paints and varnishes Titanium dioxide. Depending on the desired color intensity Mass contents of up to 5% are used. The use of organic Leads pigments because of the much finer powder particle sizes in these types of pigments and Although lower density to mass, even at intense coloring less than 1%. Because of the high agglomeration tendency so finer Pigments is their uniform incorporation and Dispersion in non-pasty Substances such as calcium sulfate hemihydrate powder problematic. she are therefore of little importance. Completely unsuited are against it water-soluble Dyes. They lead because of their water solubility to that Increased dye concentrations occur in all areas of the dental plaster object where there is evaporation of water, e.g. from mixing water surpluses.

All Try the ones previously described with their default settings Dental calcium sulfate hemihydrate products using conventional To modify pigments so that it the task of the invention to solve was, led not to success. The photoinitiators of the waxy to be processed Model material and the light-curing Plastics have their reaction maximum between 360 and 420 nm.

There These materials are translucent, was first tried, a blue pigmented Calcium sulfate hemihydrate product in its blue color closer to the polymerization- Bring color. Despite color shift were too long Polymerization times, namely up to 30 minutes and more. Especially the waxy objects have doing so under the influence of heat deformed. Their deformations were then by the polymerization frozen.

unsuccessful were also experiments with particularly white calcium sulfate hemihydrate products. Your whiteness was supplemented by the addition of up to 5% titanium dioxide and in terms of Strength just allowed quantities of very white Calcium carbonate increased. There were no reductions the polymerization times.

It finally became found that yourself preferably blue pigmented products but not especially others intensely colored Change product variants like this let that one at polymerization times of less than 15 minutes, in conventional objects even 10 minutes can come. Light blue colored Gypsum models are particularly common in dentistry, because the color contrast opposite most dental materials is particularly high and therefore the dental technician more accurate work than on white Plaster models allows.

The inventive task was solved by a model material according to claim 1. Namely, that the Calcium sulfate hemihydrate products, in addition to the aforementioned fillers, Adjusting agents and color pigments, fluorescent substances mixed were. The most effective substances were those in the short-wave, this means blue-violet region of the visible spectrum, e.g. lanthanum and cerium oxides or cerlanthan mixed oxides. Especially economical is yttria doped with cerium mine mixed oxide because it is here to commercially available Fluorescent substances is. The effect in the blue-violet spectral range is also colored with blue Gypsum achieved, provided the coloring not too intense. The effect of the fluorescent pigments elevated clearly with their particle fineness. With average grain sizes around 1 μm Mass contents of 1%, while average particle sizes of 10 μm at mass contents 10% first effects show.

at organic fluorescers, all a more or less high water solubility have, surprisingly found that himself full water solubility, as present in the sodium salts of organodisulfonic acids, in contrast to the experience with water-soluble dyes no disadvantageous Consequences for the dental or dental Working on such modified gypsum brings. This is because such Because of their water solubility, fluoresceens accumulate on the plaster surface, but there at work under artificial or daylight color not to disturb. The consequence of this phenomenon is that such water-soluble Fluorescent substances are effective even at mass contents from about 0.01% become.

Claims (4)

Mineral model material based on calcium sulfate hemihydrate for the production of dental and dental plaster models whose surface fluoresces in the spectral range of 360 to 420 nm, characterized in that it is composed of: 70-99% hydraulically setting calcium sulfate hemihydrate 0-25% non-setting fillers, preferably calcium carbonate 0-5% adjusting agent, from the group of retarders, accelerators, crystallizers, nucleating agents and consistency regulators. 0-5% organic or inorganic color pigments 0.01-10% organic and / or inorganic fluorescent substances whose light emission is predominantly between 360 and 420 nm. Mineral model material according to claim 1, characterized characterized as being Fluorescent 0.01 to 1.0% water-soluble organic fluorescers are used, the predominant fluoresce in the spectral range between 360 and 420 nm. Mineral model material according to claim 1, characterized in that the fluorescent substance 0.1 to 10% of inorganic pigments are used, which fluoresce predominantly in the spectral range between 360 and 420 nm. Mineral model material according to claim 1, characterized characterized as being Fluorescent is a mixture of water-soluble organic salts with organic and inorganic pigments in a total amount from 0.05 to 5%, the total being predominantly fluoresce in the spectral range between 360 and 420 nm.